Steam cooker and related superheater

ABSTRACT

A steam cooker includes a steam generator including a heating chamber defining a volume for holding water. A heat exchanger is associated with the heating chamber so as to generate steam. A steam superheater superheats steam traveling from the heating chamber to a steam cooking chamber.

TECHNICAL FIELD

The present application relates to steam cookers and more particularly to a steam cooker including a steam superheated.

BACKGROUND

Steam cookers have been successfully employed by restaurants, hospitals and other food service operations to prepare quickly and conveniently large quantities of food. Increases in productivity and efficiency are regularly sought and therefore decreasing the time and energy needed to steam cook products would be desirable.

SUMMARY

In an aspect, a steam cooker includes a steam generator including a heating chamber defining a volume for holding water. A heat exchanger is associated with the heating chamber with the heat exchanger being configured to have hot gases pass there through in order to heat water in the heating chamber so as to generate steam. A steam superheated has a first passageway in communication with the heat exchanger to receive hot gases from the heat exchanger and a second passageway in communication with the heating chamber to receive steam from the heating chamber with the first and second passageways arranged in a heat exchange relationship where, in use, steam generated in the heating chamber travels along the second passageway while hot gases travel along the first passageway to superheat steam in the second passageway. A steam cooking chamber is in communication with the second passageway to receive superheated steam from the second passageway.

In another aspect, a steam cooker includes a steam generator including a heating chamber defining a volume for holding water. A heat exchanger is associated with the heating chamber, the heat exchanger configured to have hot gases pass there through in order to heat water in the heating chamber so as to generate steam. An exhaust stack is arranged to receive hot gases from the heat exchanger. A steam flow path receives steam from the heating chamber, the steam flow path arranged in a heat exchange relationship with the exhaust stack such that, in use, steam moving along the steam flow path is superheated by heat from hot gases traveling along the exhaust stack. A steam cooking chamber receives superheated steam from the steam flow path.

In another aspect, a method of cooking using superheated steam is provided. The method includes generating steam from water disposed in a boiler comprising a heating chamber and a heat exchanger disposed in the heating chamber where hot gases pass through the heat exchanger. The steam is superheated in a superheated having a first passageway in communication with the heat exchanger for receiving hot gases and a second passageway in communication with the heating chamber for receiving steam with the first and second passageways being in thermal communication such that steam traveling from the heating chamber along the second passageway is superheated by hot gases traveling from the heat exchanger along the first passageway. The superheated steam is introduced to a cooking chamber.

In another aspect, a steam cooker includes a steam generator including a heating chamber defining a volume for holding water and an on-board heat exchanger associated with the heating chamber. A steam path is in communication with the heating chamber to receive steam from the heating chamber and extends to a steam cooking chamber. An on-board heating mechanism located along the steam path for superheating steam traveling along the steam path to a temperature of between about 220 and 260 degrees F.

The use of superheated steam to cook food products can, in some cases, decrease cooking times and reduce the amount of energy consumed because the energy used to raise the temperature of the steam to the superheated state is energy that otherwise would have been lost through exhausted flue gases.

The details of one or more embodiments are set forth in the accompanying drawings and the description below. Other features, objects, and advantages will be apparent from the description and drawings, and from the claims.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagrammatic illustration of an embodiment of a steam cooker including a steam superheated.

FIG. 2 is a side view of an embodiment of a steam superheated.

FIG. 3 is a section view of the superheated of FIG. 2.

FIG. 4 is a diagrammatic illustration of another embodiment of a steam cooker including a steam superheated.

FIG. 5 illustrates another embodiment of a steam cooker heating chamber.

DETAILED DESCRIPTION

Referring to FIG. 1, a low-pressure steam cooker 10 includes a steam generator 12 for generating steam and a cooking chamber 14 that is in communication with the steam generator. The cooking chamber 14 is formed by an insulate housing and includes a door 15 movable between open and closed conditions. As will be described below, the steam generator 12 includes a heating chamber 18 where steam is generated and a steam superheated 16 capable of superheating the steam generated in the heating chamber under relatively low pressure conditions (e.g., in some embodiments, at most about five psi, such as about three psi).

Referring still to FIG. 1, disposed within the heating chamber 18 is a gas heat exchanger 20 in the form of a submerged heat exchange tube. As shown, heat exchanger 20 includes a helical portion 22, however, any suitable design can be used. The heat exchanger 20 is connected to a burner unit 24 (e.g., a metal fiber, fan-driven burner having a stainless steel mesh and stainless steel tube, such as a Model BCT0027, available from N.V. Acotech S.A., Kennesaw, Ga.) that is capable of generating hot gases for delivery to the heat exchanger. Heat exchanger 20 is located in the heating chamber 18 such that it can be in a heat exchange relationship with water disposed therein. While the illustrated heat exchange relationship with the water is via submersion of the heat exchanger, it is possible that hot gas could pass through ducts that are not submerged, such as ducts that run along the exterior wall of the heating chamber 18. The heating chamber 18 includes an inlet 26 for ingress of water into the heating chamber from a water source (not shown) and an outlet 28 for egress of water from the heating chamber (as when the chamber is to be drained). A valve (not shown) controls water flow into the heating chamber, e.g., to maintain a desired water level within the heating chamber 18 during steam production. Disposed between the steam superheated 16 and cooking chamber 14 is a valve 32 that controls the flow rate of superheated steam into the cooking chamber (in some embodiments, the flow rate of superheated steam from steam superheated 16 into the cooking chamber is between about 35 and about 90 pounds per hour, such as about 50 pounds per hour where the volume of the cooking chamber is between about 164 and 245 cubic inches).

Referring now to FIGS. 2 and 3, steam superheated 16 includes an outer tube 34 and an inner tube 36 disposed within the outer tube. Outer tube 34 includes an inlet coupling 38 associated with a steam outlet 37 of the heating chamber 18 and an outlet coupling 39 associated with the cooking chamber 14 (FIG. 1). Inner tube 36 includes a gas inlet 40 fluidly connected to the heat exchanger 20 and an exhaust outlet 42 for the venting of combustion gases.

Referring particularly to FIG. 3, as shown, inner tube 36 is concentrically arranged within outer tube 34 to form a steam passageway 44 between the inner and outer tubes and about the periphery of the inner tube and an exhaust passageway 47 within the inner tube. In another embodiment, the steam passageway 44 might be located alongside, but not surrounding, the exhaust passageway 47, or the exhaust passageway 47 could surround the steam passageway 44. End caps 46 and 48 interconnect the inner tube 36 and the outer tube 34 and seal the passageway 44 formed there between from the atmosphere. The end caps 46, 48 each include a mounting plate 50 having a pair of openings 52, 54, e.g., for receiving a fastener, for use in mounting the steam superheated 16. Of course, other mounting means can be utilized, such as welding. A suitable method for connecting the inner and outer tubes to the end caps is welding, as an example.

In some embodiments, the inner tube 36 has an inner diameter D₁ of between about 2.5 and 5 inches, such as about 3 inches and an outer diameter D₂ of between about 3.5 and 5.5 inches, such as about 3.5 inches. In certain embodiments, the outer tube 34 has an inner diameter D₁′ of between about 3.5 and 5.5 inches, such as 4 inches and an outer diameter D₂′ of between about 4.5 and 6 inches, such as about 4.5 inches. The length L of the passageway 44 measured between end caps 46, 48 can be between about 20 and 30 inches, such as about 25 inches. These parameters are exemplary and can be varied depending on, for example, the desired steam temperatures and pressures and the size of the steam cooker. Any suitable material can be used to form the inner and outer tubes including, for example, food contact grade materials, such as stainless steel.

Referring back to FIG. 1, during use, the heating chamber 18 is filled with an amount of water (e.g., between about 10 and 15 gallons, such as about 13 gallons) through inlet 26. The combustion gases of burner unit 24 provide a temperature that is suitable to generate steam from the water disposed within the heating chamber 18. In some embodiments, the combustion gases are at a temperature of at least about 2000 degrees F., such as about 2100 degrees F. The combustion gases are introduced to the heat exchanger 20 where heat is transferred via the surface of the heat exchanger to the water disposed in the tank. When the combustion gases have traveled through the heat exchanger 20, the gases are exhausted through the inner tube 36 and out the exhaust outlet 42.

When the water reaches a temperature sufficient to generate steam, the steam exits steam outlet 37 and is directed to inlet coupling 38 along passageway 58. As steam travels along the passageway 44 in the direction of arrow 62, the combustion gases traveling along exhaust passageway 47 in the direction of arrow 64 heat the steam via heat transfer at the outer surface of tube 36. This counter flow arrangement, in some cases, may maintain a relative constant temperature differential (in some embodiments, a temperature differential of between about 800 and 1000 degrees F.) between the hot gases traveling along passageway 47 and steam traveling along passageway 44, which can provide more efficient steam superheating compared to a flow arrangement in which both the combustion gases and steam travel in the same direction. However, in some embodiments a counterblow arrangement may not be needed or feasible. Other flow arrangements are possible.

In some embodiments, a temperature of the steam traveling along the passageway 44 is increased at least about ten percent as it approaches the outlet coupling 37, e.g., to a temperature of between about 220 and 260 degrees F., such as about 240 degrees F. To increase the temperature of the steam, in some embodiments, the temperature of the gases entering the passageway 47 is between about 900 and 1200 degrees F., such as about 1000 degrees F. The superheated steam is then directed to the cooking chamber 14 along passageway 60 and the hot gases are vented from the exhaust passageway 47.

In other embodiments, multiple steam super heaters 16 can be provided to supply superheated steam to the cooking chamber 14. Further, a single steam superheated could be connected to feed superheated steam to more than one cooking chamber.

It is to be clearly understood that the above description is intended by way of illustration and example only and is not intended to be taken by way of limitation, and that changes and modifications are possible. For example, while the use of a heat exchanger that receives combustion gases is primarily described, units that utilize other types of heat exchangers could be provided. For example, reference is made to FIG. 5 in which a heating tank chamber 100 includes a submerged electrical, resistive heating element 102. The resistive element 102 could be contained within a heating plate 104 that makes up the bottom surface of the chamber 100. In such an embodiment the steamer would include a wall plug and related power supply for energizing the element 102. Further, while the use of combustion gases traveling along the exhaust stack is primarily described as being used for superheating the steam, in another embodiment, shown in FIG. 4, a resistive heating element 110 could be located along (either within as shown or external as in the case of a restive wire wound thereabout) the steam path leading from the heating tank to the steam cooking chamber for the purpose of superheating the steam. In such an embodiment the steamer would include a wall plug and related power supply for energizing the element 102. A combination of the heating tank of FIG. 5 and superheating arrangement of FIG. 4 could also be provided. An additional gas heating element could also be located for superheating the steam. 

1. A steam cooker comprising: a steam generator including a heating chamber defining a volume for holding water; a heat exchanger associated with the heating chamber, the heat exchanger configured to have hot gases pass therethrough in order to heat water in the heating chamber so as to generate steam; and a steam superheater having a first passageway in communication with the heat exchanger to receive hot gases from the heat exchanger and a second passageway in communication with the heating chamber to receive steam from the heating chamber, the first and second passageways arranged in a heat exchange relationship; wherein, in use, steam generated in the heating chamber travels along the second passageway while hot gases travel along the first passageway in a generally opposite second flow direction to superheat steam in the second passageway, the hot gases and the steam travel in a counter flow arrangement along the first and second passageways for reducing temperature differential variance between the hot gases and the steam; and a steam cooking chamber in communication with the second passageway to receive superheated steam from the second passageway; wherein the first passageway comprises an exhaust conduit in communication with the heat exchanger and the second passageway comprises a steam conduit in communication with the heating chamber; wherein the exhaust conduit is disposed in the steam conduit, the second passageway defined between the steam conduit and the exhaust conduit; wherein pressure in the heating chamber is at least about three psi while steam is being generated therein; wherein steam traveling along the second passageway is heated to a temperature of at least about 240 degrees F.
 2. The steam cooker of claim 1, wherein the exhaust conduit is disposed coaxially within the steam conduit.
 3. The steam cooker of claim 1, wherein, in use, steam flows about a periphery of the exhaust conduit during superheating.
 4. The steam cooker of claim 1, wherein only a portion of the exhaust conduit is disposed in the steam conduit.
 5. The steam cooker of claim 1, wherein the exhaust conduit comprises at least part of an upright exhaust stack.
 6. The steam cooker of claim 1, wherein an inlet of the steam conduit is spaced apart from an outlet of the steam conduit such that, in use, steam moving along the second passageway in a first direction from the inlet of the steam conduit toward the outlet of the steam conduit is superheated by hot gases traveling along the exhaust conduit in a second direction to provide the counter flow arrangement.
 7. The steam cooker of claim 1, wherein temperature of the steam exiting the heating chamber increases at least ten percent while traveling along the second passageway, pressure in the heating chamber is no more than about five psi while steam is being generated therein.
 8. A steam cooker comprising: a steam generator including a heating chamber defining a volume for holding water; a heat exchanger associated with the heating chamber, the heat exchanger configured to have hot gases pass therethrough in order to heat water in the heating chamber so as to generate steam; an exhaust stack arranged to receive hot gases from the heat exchanger; and a steam flow path downstream of the heating chamber that receives steam from the heating chamber, the steam flow path arranged in a heat exchange relationship with the exhaust stack such that, in use, steam moving along the steam flow path is superheated by heat from hot gases traveling along an exhaust path, wherein temperature of the steam that has exited the heating chamber increases at least about ten percent as a result of being superheated wherein steam traveling along the steam flow path is heated to a temperature of at least about 240 degrees F. and steam is generated in the heating chamber under a pressure of between about three psi and five psi; and a steam cooking chamber for receiving superheated steam from the steam flow path; wherein the exhaust path comprises the exhaust stack and at least part of the steam flow path is formed by a space between an outer surface of the exhaust stack and an inner surface of a conduit disposed about the exhaust stack; wherein the steam is introduced to the space at a location remote from the heating chamber such that the steam travels along the space toward the heating chamber while being superheated by heat from the hot gases traveling along the exhaust path.
 9. The steam cooker of claim 8, wherein the steam flow path extends about a periphery of at least part of the exhaust path.
 10. The steam cooker of claim 8, wherein, in use, steam moves along the steam flow path in a downward direction while hot gases move upward along the exhaust path.
 11. A method of cooking using superheated steam, the method comprising: generating steam from water disposed in a boiler comprising a heating chamber and a heat exchanger disposed in the heating chamber where hot gases pass through the heat exchanger, the steam being generated in the heating chamber under pressure conditions of at least about three psi; outputting steam from the heating chamber via a heating chamber outlet; superheating the steam in a superheater to a temperature of at least about 240 degrees F., the superheater having a first passageway in communication with the heating exchanger for receiving hot gases and a second passageway in communication with the heating chamber outlet for receiving steam, the first and second passageways being in thermal communication such that steam traveling from the heating chamber along the second passageway is superheated by hot gases traveling along the first passageway; and introducing superheated steam from the superheater into a cooking chamber; wherein superheating the steam in the superheater includes directing hot gases through a steam conduit, the first passageway being defined in part by an exhaust conduit located in the steam conduit, the second passageway defined in part by a space between an outer surface of the exhaust conduit and inner surface of the steam conduit; wherein the steam is introduced to the space at a location remote from the heating chamber such that steam travels along the space toward the heating chamber while being superheated by the hot gases traveling along the first passageway.
 12. The method of claim 11, wherein superheating the steam in the superheater includes directing the hot gases along the first passageway in a first direction and directing steam along the second passageway in a second direction opposite the first direction.
 13. The method of claim 11, wherein temperature of the steam generated in the boiler is increased at least about ten percent during the step of superheating, the steam being generated in the heating chamber under pressure conditions of no more than about five psi. 